CN111795602A - Internal thread copper pipe and idle call heat exchanger - Google Patents

Abstract

The invention relates to the technical field of exchangers, in particular to an internal thread copper pipe and an air conditioner heat exchanger, which comprises a heat exchange barrel, wherein a through pipe is arranged in the heat exchange barrel, the through pipe is wound with the thread copper pipe, the two ends of the thread copper pipe are fixedly connected with connectors, a partition plate is fixedly connected in the heat exchange barrel, the bottom of the heat exchange barrel is communicated with a water tank, and the two ends of the water tank are communicated with the two ends of the heat exchange barrel through a water pump; according to the invention, water in the water tank can be pumped into the heat exchange barrel through the water pump, and the water is enabled to perform spiral motion between the partition plates due to the limiting effect of the spiral structure of the partition plates, and finally re-enter the water tank through the connecting pipe at the middle position of the bottom of the heat exchange barrel, and simultaneously flows towards the middle position of the heat exchange barrel, so that the problem that the heat radiation effect is poor due to overhigh temperature of water at the other end when the water flows in from one end is avoided, and the heat exchange effect of the heat exchanger is improved.

Description

Internal thread copper pipe and idle call heat exchanger

Technical Field

The invention relates to the technical field of exchangers, in particular to an internal thread copper pipe and an air conditioner heat exchanger.

Background

Heat exchangers are devices used to transfer heat from a hot fluid to a cold fluid to meet specified process requirements, and are an industrial application of convective and conductive heat transfer. The heat exchanger can be divided into a dividing wall type, a mixed type and a heat accumulating type according to the operation process; the degree of compactness of the surface thereof can be classified into two types, compact and non-compact.

However, the existing heat exchanger still has shortcomings when in use; firstly, the heat exchange contact area in the existing heat exchanger is limited, and the heat exchange efficiency is low; secondly, the existing heat exchanger has low utilization of natural resources, so that the energy consumption of the device is high, and the user experience is poor; finally, the existing heat exchanger is not convenient to install in use, so that the later use and maintenance of the heat exchanger are not convenient enough.

Disclosure of Invention

The invention aims to: in order to solve the problem that the use efficiency of a heat exchanger is not high enough, an internal thread copper pipe and a heat exchanger for an air conditioner are provided.

In order to achieve the purpose, the invention adopts the following technical scheme:

an internal thread copper pipe and an air conditioner heat exchanger comprise a heat exchange barrel, wherein a through pipe is arranged inside the heat exchange barrel, the through pipe is wound with a thread copper pipe, two ends of the thread copper pipe are fixedly connected with connectors, a partition plate is fixedly connected inside the heat exchange barrel, the partition plate is of a spiral structure, radiating fins are fixedly connected to the top and the bottom of the partition plate, the radiating fins penetrate through the side wall of the heat exchange barrel, the bottom of the heat exchange barrel is communicated with a water tank, and two ends of the water tank are communicated with two ends of the heat exchange barrel through a water pump; the threaded copper pipe is spirally wound, so that the length of the threaded copper pipe is increased, namely the contact area between the threaded copper pipe and the copper pipe is increased, the connectors are fixedly connected to the two ends of the threaded copper pipe, and the connectors are matched with indoor air conditioners, so that the heat exchange efficiency is improved; in addition, set up the baffle, and form independent closed helical structure between baffle and the siphunculus, increase and the contact time of the interior water of screw thread copper pipe, simultaneously, the water tank supplies water to the inside of a heat exchange section of thick bamboo simultaneously, utilizes the heat in the water absorption heat exchange section of thick bamboo, further promotes the heat exchange rate.

When the heat exchange tube works, water in the water tank can be pumped into the heat exchange tube under the action of the two water pumps at the top of the water tank, and the water performs spiral motion between the partition plates under the limiting action of the spiral structure of the partition plates; meanwhile, the two ends of the water tank are communicated through the water pumps, so that the water flow pumped into the heat exchange cylinder flows to the middle position of the heat exchange cylinder simultaneously under the action of the two water pumps, the temperature of the water at the two ends is kept constant when the water flows into the heat exchange cylinder from one end, the water at the other end is prevented from being overhigh, the water at the lower temperature at one end is not required to cool the water at the higher temperature at the other end, the heat dissipation effect is poor, and the heat exchange effect in the heat exchanger is improved; meanwhile, as the heat conduction exists between the partition board and the radiating fins, part of heat is conducted through the partition board and is transferred to the radiating fins, and one end of each radiating fin is positioned outside the heat exchanger, the radiating fins can radiate the heat under the action of natural wind, so that the heat exchange rate of the heat exchange tube is improved; in addition, because the inside heat of heat exchange section of thick bamboo is higher than the outside air, gas is heated the inflation, make the inside air density of siphunculus be less than outside air density, and then make the outside cold air get into the inside of siphunculus, and then form the convection current, the flow rate of the inside air of siphunculus has been accelerated, make the siphunculus give off the heat of inside rivers, make the utilization natural resources that this heat exchanger can be abundant, more energy-concerving and environment-protective, and better realization is cooled down the heat and is handled, accelerate heat exchange efficiency.

Preferably, the through pipe penetrates through the side walls of the two horizontal ends of the heat exchange cylinder, and the two ends of the through pipe are fixedly connected with clamping rings; the outer side of the clamping ring is connected with an installation block in a sliding mode, the installation block is in clearance fit with the clamping ring, and one side of the clamping ring is provided with a plurality of limiting grooves; steel balls are clamped in the limiting grooves, a handle is arranged on one side, away from the heat exchange barrel, of the mounting block, the inside of the handle is fixedly connected with the steel balls through a connecting rod, an extension spring is sleeved on the connecting rod, and the extension spring is located outside the mounting block; by adopting the technical scheme, the steel balls are clamped in the limiting grooves, and the heat exchanger can be stably connected through the clamping action of the steel balls and the limiting grooves; by arranging the handle, when the handle is used for pulling outwards, the steel balls fixedly connected through the connecting rod are separated from the limiting groove, so that the control is facilitated; when the heat exchanger is installed, the installation block is installed on a wall body, the clamping rings at two ends of the heat exchange cylinder are clamped inside the installation block, when the clamping rings slide towards the inside of the installation block, the steel balls are extruded at the bottoms of the clamping rings, so that the steel balls move towards one side of the handle, and after the clamping rings reach a proper position, the limiting grooves formed in the clamping rings are clamped with the steel balls under the action of the extension spring inside the handle, so that the positions of the clamping rings are stable, and the position of the heat exchange cylinder is further stable; when the heat exchange tube needs to be replaced or overhauled, the handle on one side of the mounting block is pulled outwards, the steel ball is pulled outwards through the action of the connecting rod by the handle at the moment, so that the steel ball is separated from the inside of the limiting groove, the heat exchange tube can be taken out from the inside of the mounting block at the moment, and the heat exchange tube is detached promptly.

Preferably, the threaded copper pipe is connected with the partition plate in a winding manner, a gap is formed between the threaded copper pipe and the partition plate, and the central position of the bottom of the heat exchange cylinder is communicated with the inside of the water tank through a connecting pipe; through adopting above-mentioned technical scheme, the winding is connected between screw thread copper pipe and the baffle, and there is the clearance between screw thread copper pipe and the baffle, the clearance makes water circulate effect inside it, and then take away the heat, and the bottom central point department of putting of heat exchange section of thick bamboo passes through the inside intercommunication of connecting pipe with the water tank, it flows into to store in the water tank through the connecting pipe to take away thermal water, make the water to realize the heat exchange in the heat exchange section of thick bamboo in time enter into the water tank through the connecting pipe, make the water in the water tank absorb the heat of taking away the thermal aquatic, make the temperature of taking away thermal water reduce and reach the temperature of water in the water tank, prepare for the heat exchange in the heat exchange section of thick bamboo of next round, the effect to the heat exchange in the follow-up heat exchange section of thick bamboo has been improved, and the.

Preferably, a group of elastic pieces made of tin-phosphor bronze are uniformly arranged at the end part of the radiating fin positioned outside the heat exchange cylinder, and the elastic pieces are blown by external natural wind to continuously swing, so that the radiating effect of the radiating fin is accelerated; through adopting above-mentioned technical scheme, under the effect of natural wind, can make the shell fragment take place to swing for the reduction to the temperature on the fin, thereby improved the inside radiating efficiency of heat exchange tube, in addition, make the shell fragment by tin phosphor bronze, the antioxidant power of its shell fragment improves, and hardness and toughness also obvious improvement, make the shell fragment under the effect of natural wind, continuously shake and reset, do not influence the life of shell fragment.

Preferably, a rotating fan is rotatably arranged between the adjacent elastic sheets through a rotating shaft; the rotating shaft is formed by overlapping a plurality of layers of air bags, a refrigerant is placed in each layer of air bag, and the outlet on each layer of air bag is larger closer to the end part of the radiating fin; by adopting the technical scheme, when the force of natural wind is applied, on one hand, the elastic sheet swings, on the other hand, the rotating fan rotates, the rotating fan accelerates the dissipation of heat on the radiating fin, meanwhile, due to the swinging of the rotating fan and the elastic sheet, the air bag can be extruded or stretched, when the air bag is stretched, the heat on the radiating fin is sucked into the air bag, and the air bag and the refrigerant in the air bag act to realize cooling; when the air bag is extruded, the refrigerant in the air bag is extruded out and acts on the end part of the radiating fin, so that the heat on the radiating fin is reduced; meanwhile, the outlet on each layer of air bag is closer to the end part of the radiating fin and is larger, so that the refrigerant extruded by each layer of air bag can act on the radiating fin, the temperature on the radiating fin is reduced, and the heat exchange effect of the heat exchanger is improved.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that:

1. according to the invention, water in the water tank can be pumped into the heat exchange cylinder under the action of the two water pumps at the top of the water tank, and the water is enabled to perform spiral motion between the partition plates under the limiting action of the spiral structure of the partition plates, and finally re-enter the water tank through the connecting pipe at the middle position of the bottom of the heat exchange cylinder to perform the next round of circulation; meanwhile, under the action of the two water pumps, water flows to the middle position of the heat exchange barrel simultaneously, so that the problem that when the water flows in from one end, the temperature of the water at the other end is too high to influence heat dissipation is avoided, and the heat exchange efficiency of the heat exchanger is improved.

2. In the invention, through the heat conduction between the partition board and the radiating fins, part of heat is conducted through the partition board and reaches the radiating fins, so that the radiating fins can radiate the heat under the action of natural wind, the heat exchange rate of the heat exchange barrel is improved, in addition, because the internal heat of the heat exchange barrel is higher than that of external air, and the gas expands under the action of heat, the air density inside the through pipe is smaller than that of the external air, so that the external cold air enters the through pipe, convection is further formed, the flow rate of the air inside the through pipe is accelerated, and the heat of internal water flow is radiated by the through pipe, so that the heat exchanger can fully utilize natural resources, and is more energy-saving and environment-friendly.

3. According to the invention, the clamping rings at two ends of the heat exchange tube are clamped in the mounting block, and the limiting grooves formed in the clamping rings are clamped with the steel balls under the action of the extension springs in the handles, so that the positions of the clamping rings are stable, the position of the heat exchange tube is further stable, when the heat exchange tube needs to be replaced or overhauled, the handle at one side of the mounting block is pulled outwards, the steel balls are pulled outwards under the action of the connecting rod to be separated from the limiting grooves, the heat exchange tube can be taken out from the inside of the mounting block, and the heat exchange tube can be dismounted.

Drawings

Fig. 1 is a schematic view of an internal thread copper pipe and an internal structure of a heat exchanger for an air conditioner according to the present invention;

FIG. 2 is a schematic view of the mounting and connecting structure of the internal thread copper pipe and the heat exchanger for air conditioner according to the present invention;

FIG. 3 is a schematic side view of the copper pipe with internal threads and the heat exchanger for air conditioner according to the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 1 at A;

FIG. 5 is a partial cross-sectional view of a rotating shaft according to the present invention;

illustration of the drawings:

1. a heat exchange tube; 2. pipe passing; 3. mounting blocks; 4. a handle; 5. a connector; 6. a threaded copper tube; 7. a partition plate; 8. a heat sink; 81. a spring plate; 82. a rotating shaft; 821. an air bag; 83. rotating the fan; 9. a water tank; 10. a connecting pipe; 11. a water pump; 12. a snap ring; 13. steel balls; 14. an extension spring; 15. a limiting groove; 16. a connecting rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution:

an internal thread copper pipe and an air conditioner heat exchanger comprise a heat exchange barrel 1, wherein a through pipe 2 is arranged inside the heat exchange barrel 1, a thread copper pipe 6 is wound on the through pipe 2, connectors 5 are fixedly connected to two ends of the thread copper pipe 6, a partition plate 7 is fixedly connected inside the heat exchange barrel 1, the partition plate 7 is of a spiral structure, radiating fins 8 are fixedly connected to the top and the bottom of the partition plate 7, the radiating fins 8 penetrate through the side wall of the heat exchange barrel 1, the bottom of the heat exchange barrel 1 is communicated with a water tank 9, and two ends of the water tank 9 are communicated with two ends of the heat exchange barrel 1 through a water pump 11; according to the invention, the threaded copper pipe 6 is arranged in a spiral winding manner, the length of the threaded copper pipe is increased, namely the contact area between the threaded copper pipe 6 and the copper pipe 2 is increased, the connectors 5 are fixedly connected to both ends of the threaded copper pipe 6, and the connectors 5 are matched with an indoor air conditioner, so that the heat exchange efficiency is accelerated; in addition, set up baffle 7, and form independent closed helical structure between baffle 7 and the siphunculus 2, increase and the contact time of the interior water of screw thread copper pipe 6, simultaneously, water tank 9 supplies water to the inside of heat exchange tube 1 simultaneously, utilizes the heat in the water absorption heat exchange tube 1, further promotes the heat exchange rate.

When the heat exchange tube works, water in the water tank 9 is pumped into the heat exchange tube 1 under the action of the two water pumps 11 on the top of the water tank 9, and the water performs spiral motion between the partition plates 7 under the limiting action of the spiral structure of the partition plates 7; meanwhile, as the two ends of the water tank 9 are communicated through the water pumps 11, under the action of the two water pumps 11, the water flow pumped into the heat exchange cylinder 1 flows to the middle position of the heat exchange cylinder 1 at the same time, so that the temperature of the water at the two ends is kept constant, and the water at the lower temperature at one end is not needed to cool the water at the higher temperature at the other end, so that the heat dissipation effect is poor, and the heat exchange effect in the heat exchanger 1 is improved; meanwhile, as the heat conduction exists between the partition plate 7 and the radiating fins 8, part of heat is conducted through the partition plate 7 and is transmitted to the radiating fins 8, and one end of each radiating fin 8 is positioned outside the heat exchanger 1, so that the radiating fins 8 radiate the heat under the action of natural wind, and the heat exchange rate of the heat exchange cylinder 1 is improved; in addition, because the inside heat of heat exchange tube 1 is higher than the outside air, gas is heated the inflation, make the inside air density of siphunculus 2 be less than outside air density, and then make the outside cold air get into the inside of siphunculus 2, and then form the convection current, the flow rate of the inside air of siphunculus 2 has been accelerated, make siphunculus 2 give off the heat of inside rivers, make the utilization natural resources that this heat exchanger can be abundant, more energy-concerving and environment-protective, and better realization is cooled down the heat and is handled, accelerate heat exchange efficiency.

As an embodiment of the present invention, the through pipe 2 penetrates through the horizontal two-end side walls of the heat exchange tube 1, and the clamping rings 12 are fixedly connected to both ends of the through pipe 2; the outer side of the clamping ring 12 is connected with a mounting block 3 in a sliding manner, the mounting block 3 is in clearance fit with the clamping ring 12, and one side of the clamping ring 12 is provided with a plurality of limiting grooves 15; steel balls 13 are clamped in the limiting grooves 15, a handle 4 is arranged on one side, away from the heat exchange barrel 1, of the mounting block 3, the inside of the handle 4 is fixedly connected with the steel balls 13 through a connecting rod 16, an extension spring 14 is sleeved on the connecting rod 16, and the extension spring 14 is located outside the mounting block 3; by adopting the technical scheme, the steel balls 13 are clamped in the limiting grooves 15, and the heat exchanger can be stably connected through the clamping action of the steel balls 13 and the limiting grooves 15; by arranging the handle 4, when the handle 4 is used for pulling outwards, the steel balls 13 fixedly connected through the connecting rod 16 are separated from the limiting groove 15, so that the control is facilitated; when the heat exchanger is installed, the installation block 3 is firstly installed on a wall body, the clamping rings 12 at two ends of the heat exchange tube 1 are clamped in the installation block 3, when the clamping rings 12 slide towards the inside of the installation block 3, the steel balls 13 are extruded at the bottom of the clamping rings 12, so that the steel balls 13 move towards one side of the handle 4, after the clamping rings 12 reach a proper position, the limiting grooves 15 formed in the clamping rings 12 are clamped with the steel balls 13 under the action of the extension springs 14 in the handle 4, so that the position of the clamping rings 12 is stable, and further the position of the heat exchange tube 1 is stable; when the heat exchange tube 1 needs to be replaced or overhauled, the handle 4 on one side of the mounting block 3 is pulled outwards, the steel ball 13 is pulled outwards by the handle 4 at the moment through the action of the connecting rod 16, so that the steel ball is separated from the inside of the limiting groove 15, at the moment, the heat exchange tube 1 can be taken out from the inside of the mounting block 3, and the heat exchange tube 1 is detached.

As an embodiment of the invention, the threaded copper tube 6 and the partition plate 7 are wound and connected, a gap is formed between the threaded copper tube 6 and the partition plate 7, and the central position of the bottom of the heat exchange cylinder 1 is communicated with the inside of the water tank 9 through a connecting tube 10; by adopting the technical scheme, the threaded copper pipe 6 is connected with the partition plate 7 in a winding way, and a gap is formed between the threaded copper pipe 6 and the partition plate 7, so that water can circulate in the gap, then takes away heat, the central position of the bottom of the heat exchange cylinder 1 is communicated with the inside of the water tank 9 through a connecting pipe 10, the water taking away heat flows into the water tank 9 through the connecting pipe 10 to be stored, so that the water which has performed heat exchange in the heat exchange tube 1 can enter the water tank 9 through the connecting pipe 10 in time, make the water in the water tank 9 absorb the heat of taking away thermal aquatic for the temperature of taking away thermal water reduces and reaches the temperature of water in the water tank 9, for the next round of heat exchange in the heat exchange tube 1 makes preparation, has improved the effect to heat exchange in the follow-up heat exchange tube 1, and has guaranteed the circulation of this heat exchanger work.

As an embodiment of the present invention, a set of elastic pieces 81 made of tin-phosphor bronze is uniformly arranged at the end of the heat dissipation plate 8 located outside the heat exchange tube 1, and the elastic pieces 81 are blown by external natural wind, so that the elastic pieces 81 continuously swing, and the heat dissipation effect of the heat dissipation plate 8 is accelerated; through adopting above-mentioned technical scheme, under the effect of natural wind, can make shell fragment 81 take place the swing for the reduction to the temperature on the fin 8, thereby improved the radiating efficiency of heat exchange tube 1 inside, in addition, make shell fragment 81 by tin phosphor bronze, its shell fragment 81's oxidation resistance improves, and hardness and toughness also obvious improvement, make shell fragment 81 under the effect of natural wind, continuously shake and reset, do not influence the life of shell fragment 81.

As an embodiment of the present invention, a rotating fan 83 is rotatably installed between adjacent elastic sheets 81 through a rotating shaft 82; the rotating shaft 82 is formed by overlapping a plurality of layers of air bags 821, refrigerant is placed in each layer of air bag 821, and the outlet of each layer of air bag 821 is larger closer to the end part of the radiating fin 8; by adopting the technical scheme, when the force of natural wind is applied, on one hand, the elastic sheet 81 can swing, on the other hand, the rotating fan 83 can rotate, the rotating fan 83 accelerates the dissipation of heat on the radiating fin 8, meanwhile, due to the swinging of the rotating fan 83 and the elastic sheet 81, the air bag 821 can be extruded or stretched, and when the air bag 821 is stretched, the heat on the radiating fin 8 is pumped into the air bag 821 to be acted with the refrigerant in the air bag 821 to realize the cooling; when the air bag 821 is pressed, the refrigerant in the air bag 821 is extruded and acts on the end part of the radiating fin 8, so that the heat on the radiating fin 8 is reduced; meanwhile, the outlet on each layer of the air bag 821 is closer to the end part of the radiating fin 8 and is larger, so that the refrigerant extruded out from each layer of the air bag 821 can act on the radiating fin 8, the temperature on the radiating fin 8 is reduced, and the heat exchange effect of the heat exchanger is improved.

The working principle is as follows: when the heat exchanger is installed, the installation block 3 is firstly installed on a wall body, the clamping rings 12 at two ends of the heat exchange tube 1 are clamped in the installation block 3, when the clamping rings 12 slide towards the inside of the installation block 3, the steel balls 13 are extruded at the bottom of the clamping rings 12, so that the steel balls 13 move towards one side of the handle 4, after the clamping rings 12 reach a proper position, the limiting grooves 15 formed in the clamping rings 12 are clamped with the steel balls 13 under the action of the extension springs 14 in the handle 4, so that the position of the clamping rings 12 is stable, and further the position of the heat exchange tube 1 is stable; when the heat exchange tube 1 needs to be replaced or overhauled, the handle 4 on one side of the mounting block 3 is pulled outwards, the handle 4 pulls the steel ball 13 outwards through the action of the connecting rod 16, so that the steel ball is separated from the inside of the limiting groove 15, and at the moment, the heat exchange tube 1 can be taken out from the inside of the mounting block 3, namely the heat exchange tube 1 is disassembled; when the heat exchanger works, water in the water tank 9 is pumped into the heat exchange barrel 1 under the action of the two water pumps 11 at the top of the water tank 9, and the water performs spiral motion between the partition plates 7 under the limiting action of the spiral structure of the partition plates 7; meanwhile, as the two ends of the water tank 9 are communicated through the water pumps 11, under the action of the two water pumps 11, the water flow pumped into the heat exchange cylinder 1 flows to the middle position of the heat exchange cylinder 1 at the same time, so that the temperature of the water at the two ends is kept constant, and the water at the lower temperature at one end is not needed to cool the water at the higher temperature at the other end, so that the heat dissipation effect is poor, and the heat exchange effect in the heat exchanger 1 is improved; meanwhile, as the heat conduction exists between the partition plate 7 and the radiating fins 8, part of heat is conducted through the partition plate 7 and is transmitted to the radiating fins 8, and one end of each radiating fin 8 is positioned outside the heat exchanger 1, so that the radiating fins 8 radiate the heat under the action of natural wind, and the heat exchange rate of the heat exchange cylinder 1 is improved; in addition, because the internal heat of the heat exchange cylinder 1 is higher than that of the external air, and the gas expands when heated, the air density inside the through pipe 2 is lower than that of the external air, so that the external cold air enters the through pipe 2 to form convection, the flow rate of the air inside the through pipe 2 is accelerated, the heat of the internal water flow is dissipated by the through pipe 2, the heat exchanger can fully utilize natural resources, is more energy-saving and environment-friendly, and better realizes the cooling treatment of the heat, and the heat exchange efficiency is accelerated; the inside intercommunication through connecting pipe 10 and water tank 9 is put to department in the bottom central point of heat exchange section of thick bamboo 1, take away thermal water and store in flowing into water tank 9 through connecting pipe 10, make the water to realizing the heat exchange in heat exchange section of thick bamboo 1 in time enter into water tank 9 through connecting pipe 10, make the water in the water tank 9 absorb the heat of taking away thermal aquatic, make the temperature of taking away thermal water reduce and reach the temperature of water tank 9 internal water, prepare for the heat exchange in the heat exchange section of thick bamboo 1 of next round, the effect of heat exchange in follow-up heat exchange section of thick bamboo 1 has been improved, and the circulation of this heat exchanger work has been guaranteed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (6)

1. The utility model provides an internal thread copper pipe and idle call heat exchanger, its characterized in that, includes heat exchange tube (1), the inside of heat exchange tube (1) is provided with siphunculus (2), and on siphunculus (2) around being equipped with screw thread copper pipe (6) to the equal fixedly connected with connector (5) in both ends of screw thread copper pipe (6), the inside fixedly connected with baffle (7) of heat exchange tube (1), baffle (7) are spiral structure, and the top of baffle (7) and the equal fixedly connected with fin (8) in bottom to fin (8) run through the lateral wall of heat exchange tube (1), and the bottom intercommunication of heat exchange tube (1) has water tank (9), the both ends of water tank (9) are passed through water pump (11) and are linked together with the both ends of heat exchange tube (1).

2. The internally threaded copper tube and air conditioning heat exchanger as recited in claim 1, wherein the through tube (2) penetrates through the side walls of both horizontal ends of the heat exchange tube (1), and both ends of the through tube (2) are fixedly connected with clamping rings (12); the outside sliding connection of joint ring (12) has installation piece (3), and clearance fit between installation piece (3) and joint ring (12) to a plurality of spacing grooves (15) have been seted up to one side of joint ring (12).

3. The heat exchanger for the internal thread copper pipe and the air conditioner is characterized in that steel balls (13) are clamped in the limiting grooves (15), a handle (4) is arranged on one side, away from the heat exchange barrel (1), of the mounting block (3), the inside of the handle (4) is fixedly connected with the steel balls (13) through a connecting rod (16), a tension spring (14) is sleeved on the connecting rod (16), and the tension spring (14) is located outside the mounting block (3).

4. A heat exchanger for air conditioner and internally threaded copper pipe according to claim 3, wherein the threaded copper pipe (6) is wound around the partition plate (7) with a gap between the threaded copper pipe (6) and the partition plate (7), and the heat exchange tube (1) is communicated with the inside of the water tank (9) through a connection pipe (10) at the bottom center position.

5. The heat exchanger for air conditioner and internally threaded copper pipe according to claim 4, wherein a set of spring plates (81) made of tin-phosphor bronze are uniformly arranged at the end of the heat radiating fins (8) located outside the heat exchange tube (1), and the spring plates (81) are blown by external natural wind, so that the spring plates (81) continuously swing, and the heat radiating effect of the heat radiating fins (8) is accelerated.

6. The internally threaded copper tube and heat exchanger for air conditioners as claimed in claim 5, wherein a rotating fan (83) is rotatably mounted between adjacent spring plates (81) through a rotating shaft (82); the rotating shaft (82) is formed by overlapping a plurality of layers of air bags (821), refrigerant is placed in each layer of air bag (821), and the outlet of each layer of air bag (821) is larger closer to the end part of the radiating fin (8).

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